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SR3/SR 304 Bremerton Interchange Improvements Project May 19, 2015 Methods & Assumptions Document
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APPENDIX A___________________________________________
SR 3/SR 304 Bremerton Interchange Improvements Project
Methods and Assumption Document
May 19, 2015
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SR 3/SR 304 Bremerton Interchange Improvements Project
Draft Methods and Assumptions Document
Appendix A
May 19, 2015
Olympic Region Planning P. O. Box 47440 Olympia, WA 98504-7440 Phone: 360-357-2644
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Stakeholder Acceptance
The undersigned parties, including all members of the team from WSDOT, concur with the Interchange Justification Report Methods and Assumptions for the SR 3/SR 304 Bremerton Interchange Improvements project as presented in this document:
(1) Participation on the Stakeholders Committee and/or signing of this document does not constitute approval of the SR 3/SR 304 Bremerton Interchange Improvements project Interchange Justification Report.
(2) All members of the Stakeholder Committee will accept this document as a guide and reference as the study progresses through the various stages of project development. If there are any agreed upon changes to the assumptions in this document a revision will be created, endorsed and signed by all the stakeholders.
At the time this Methods and Assumptions Document was signed, the latest version of the WSDOT Design Manual Chapter 550 was dated July 2014.
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Table of Contents_____________________________________
Policy Point #1 – Need for the Access Point Revision ................................................. Page 9
Introduction ........................................................................................................... Page 9
Project Description .............................................................................................. Page 10
Policy Point #2 – Reasonable Alternatives ................................................................. Page 12
Policy Point #3 – Operational and Collision Analysis ................................................ Page 16
Analysis Years and Analysis Periods ................................................................... Page 16
Current Year ........................................................................................................ Page 16
Opening Year ...................................................................................................... Page 17
Design Year......................................................................................................... Page 19
Study Area and Project Limits ............................................................................. Page 21
Traffic Operations Analysis .................................................................................. Page 22
Methodology ........................................................................................................ Page 22
Software .............................................................................................................. Page 22
Results to be reported ......................................................................................... Page 22
Travel Forecast ................................................................................................... Page 23
Network Assumptions .......................................................................................... Page 23
Traffic Volume Development ............................................................................... Page 23
Selection of Measure of Effectiveness ................................................................. Page 23
Collision Analysis ................................................................................................ Page 24
Policy Point #4 – Access Connections and Design .................................................... Page 26
Policy Point #5 – Land Use and Transportation Plans ............................................... Page 27
Policy Point #6 – Future Interchanges ......................................................................... Page 27
Policy Point #7 – Coordination..................................................................................... Page 28
Policy Point #8 – Environmental Processes ............................................................... Page 28
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Acronyms__________________________________________
EB Eastbound
FHWA Federal Highway Administration
GP General Purpose
HCM Highway Capacity Manual
HOV High Occupancy Vehicle
HQ WSDOT’s Headquarters Office
HSP Highway System Plan
IJR Intersection Justification Report
LEAP Legislative Evaluation and Accountability Program
LOS Level of Service
M/A Methods and Assumptions Document
MOE Measures of Effectiveness
NB Northbound
OR Olympic Region
PSNS Puget Sound Naval Shipyard
SB Southbound
SR State Route
TDM Transportation Demand Management
WSF Washington State Ferries
WB Westbound
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Policy Point #1 – Need For the Access Point Revision
Introduction Project leads, proponents, and other team members
As sponsors of the project, the following individual groups set the goals and requirements for the project and its deliverables. WSDOT’s OR Planning office is the study lead. The study’s structure consisted of a working group and an internal technical team.
The working group committee is comprised of technical level representatives from:
Communities • Bremerton • Kitsap County • Kitsap Transit • Naval Base Kitsap • Port Orchard
WSDOT • HQ Design • HQ Highway Access • HQ Traffic • OR Project Development • OR Planning • OR Traffic.
The internal technical team consists of members from WSDOT’s HQ and OR Traffic, and OR Planning with VISSIM traffic analysis consultant support from Parametrix.
The study lead also coordinated with the Suquamish Tribe and the West Sound Cycling Club.
Background Information
The SR 3/SR 304 interchange is located in Bremerton, Washington; the SR 3/SR 304 interchange provides an important freeway to freeway connection between two major highways. The interchange is an important connection which moves people and goods via commuter, freight, and other multimodal traffic through the City of Bremerton, Kitsap County and communities and regions beyond. SR 3 is a north-south highway approximately sixty miles in length that runs between the City of Shelton in Mason County and SR 104 in the vicinity of the Hood Canal in Kitsap County. SR 3 provides a critically important north-south link in the regional transportation system in Kitsap and Mason counties serving as a primary regional transportation principle arterial, a key freight route and a commuter highway.
SR 304 is an east-west highway three miles in length, located within the City of Bremerton, connecting SR 3 with downtown Bremerton and the WSF’s Bremerton ferry terminal. SR 304 also provides access to the PSNS. The naval shipyard with its intermediate maintenance facility is the Pacific Northwest’s largest naval shore facility, and one of Washington State’s largest industrial installations. Besides the WSF terminal, the major traffic generator along this route is the PSNS.
While serving as a major regional freight corridor, SR 3 is also a vital link for the urban communities of Silverdale, Chico and Gorst along the corridor as well as the primary commuter route for the three naval bases on the Kitsap Peninsula (PSNS, Bangor and Keyport).
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Policy Point #1 – Need for the Access Point Revision Introduction Background Information continued
The current corridor geometric configurations contribute to the PM peak congestion that is being experienced along these corridors. SR 3 SB prior to the interchange merges from two lanes to one lane and SR 304 WB merges from two lanes to one lane. After SR 3 SB and SR 304 WB merge, SR 3 continues as a 2-lane facility. With the anticipated growth in traffic volumes in the opening year (2020) and future year (2040), congestion levels are anticipated to increase, and travel time in the corridor will worsen.
Facilities that will be affected by the project
The SR 3 and SR 304 interchange and the Loxie Eagans Boulevard SB on-ramp will be directly affected by this project.
Project Description
The purpose of this study is to improve mobility by eliminating the bottleneck along SB SR 3 in the vicinity of the SR 3/SR 304 interchange where two lanes merge into one.
The 2012 Supplemental Budget identified a proviso as part of LEAP to begin environmental documentation and preliminary design to expedite project delivery.
The legislature appropriated funds for the SR 3/SR 304 Bremerton Interchange Improvements project to be used to advance the design, preliminary engineering and rights of way acquisition. Funds are to be used to advance the emergent, initial development of the project for the purpose of expediting delivery.
The WSDOT’s 2007-2026 HSP and the 2011-2030 HSP identifies the SR 3/SR 304 interchange as a bottleneck where congestion conditions currently occur in the PM peak hours along SR 3 SB in the vicinity of the SR 3/SR 304 interchange where the two SB lanes merge into one. The SR 3/SR 304 interchange was also identified as a 2013 unfunded system investment by WSDOT. The mobility LOS is also below the adopted service objective in the PM peak period at this location. The resulting congestion increases delay and travel time affecting safety and imposing inconvenience for motorized travelers, and creates challenges for non-motorized travelers using the state highway.
Existing Roadway Configuration
SR 3 is a four-lane (two lanes each direction) divided highway in the vicinity of the Loxie Eagans Boulevard interchange. SR 3 SB has an auxiliary lane between the SR 310/Auto Center Way on-ramp and the Loxie Eagans Boulevard off-ramp, and SR 3 NB has an auxiliary lane between the SR 304 WB on-ramp and the Loxie Eagans Boulevard off-ramp.
At the SR 3/SR 304 interchange, SR 3 SB merges from two lanes to one lane. The SR 304 on-ramp connects to SR 3 SB as an add-lane, and SR 3 SB maintains two lanes between SR 304 and SR 16. SR 3 NB is also two lanes between SR 16 and SR 304.
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Policy Point #1 – Need For the Access Point Revision Project Description Existing Roadway Configuration continued
North of Farragut Avenue, SR 304 is four-lane arterial with a landscaped center median. South of Farragut Avenue to Charleston Boulevard, SR 304 is a six-lane arterial with a landscaped center median. In the WB direction, the inside lane is a high occupancy vehicle (HOV) lane.
The HOV lane designation ends east of the SR 3/SR 304 interchange, and the right lane drops at the on-ramp to SR 3 NB. The two remaining WB lanes merge to one lane prior to the SR 304 WB undercrossing.
Existing Traffic Operations
Findings from the analysis demonstrate that there are two locations in the study area where vehicle volumes exceed available roadway capacity during the PM commute period as follows:
• Where SR 3 SB merges from two lanes to one lane south of the Loxie Eagans interchange; this location is congested for approximately 2 hours 45 minutes, and queuing extends through the Loxie Eagans interchange.
• Where SR 304 WB merges from two lanes to one lane east of the SR 3/SR 304 interchange: This location is congested for approximately 1 hour 45 minutes. Queuing in the GP lane extends back to the Charleston Boulevard intersection. The HOV lane allows transit, vanpools and carpools to bypass the congested GP lane, but HOV vehicles experience congestion once the HOV lane terminates. There is no substantial congestion on SR 3 NB or SR 304 EB in the PM peak.
All intersections operate a LOS D or better with the following two exceptions: 1. Loxie Eagans Boulevard and SR 3 SB ramps – the SB approach to this stop-
controlled intersection operates at LOS E during the PM peak hour. 2. SR 3 and Sam Christopherson Boulevard – This signalized intersection operates
at LOS E during the PM peak hour. Note: In some cases, congestion extends beyond the limits of the model, and vehicles are effectively queuing outside of the model.
Facilities that will be affected by the project The SR 3 and SR 304 interchange and the Loxie Eagans Boulevard SB on-ramp will be directly affected by this project.
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Policy Point #2 Reasonable Alternatives
Describe the reasonable alternatives that have been evaluated.
The following five alternatives were identified to improve the traffic flow at the SR 3/SR 304 interchange.
Alternative 1: Southbound SR 3: Hard Shoulder Running
This alternative investigates opening the SB SR 3 shoulder to traffic on weekdays from 3-6 PM. Those hours often see the heaviest traffic volumes. The shoulder along SR 3 SB would be open to traffic during those hours in the vicinity of the SR 3/SR 304 interchange where the two SB lanes merge into one. This alternative was removed from further considered because it doesn’t provide a 24-hour solution; it moves the merge points further downstream; and bike capacity is lost through the SR 3/SR 304 interchange curve.
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Policy Point #2 Reasonable Alternatives Describe the reasonable alternatives that have been evaluated continued
Alternative 2: Restripe to 2 Lanes This alternative restripes the existing roadway to create two lanes on SR 3 SB in the area between the Bremerton Wastewater Treatment Plan and the SR 3/SR 304 interchange merge. Two lanes currently merge into one at this location. This alternative was identified as the low cost and short term solution with a planning level cost of $3.77 million.
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Policy Point #2 Reasonable Alternatives Describe the reasonable alternatives that have been evaluated continued
Alternative 3: Construct to 2 Lanes
This alternative demolishes and rebuilds the SR 304 on-ramp over SR 3 to accommodate two lanes on SR 3 SB in the area between the Bremerton Wastewater Treatment Plant and the SR 3/SR 304 interchange merge. This alternative has a planning level cost estimate of $6.80 million. Alternative 2 is more cost effective for the same benefit.
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Policy Point #2 Reasonable Alternatives Describe the reasonable alternatives that have been evaluated continued
Alternative 4: Southbound SR 3: Add Third Lane from SR 304 to Gorst
This alternative would add a 3rd Lane from the SR 304 on-ramp to Gorst. SB SR 3 from the SR 304 on-ramp to Gorst would be widened to create three at grade lanes. At Gorst the 3rd lane would tie into the existing three lane section leading to SR 16. Crews would also restripe SR 3 SB to two lanes in the area between the Bremerton Wastewater Treatment Plant.
This alternative is the ultimate solution, however it’s expensive. The planning level cost estimate is $158 million.
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Policy Point #2 Reasonable Alternatives Describe the reasonable alternatives that have been evaluated. continued
Alternative 5: Transportation Demand Management (TDM)
This alternative assumed a reduction in future traffic volumes through the implementation of TDM strategies. The focus of the traffic analysis was not on the specific strategies used, but on the effect of removing trips from the transportation network. The opening year (2020) analysis assumed a five percent reduction in traffic volumes, and the future year (2040) analysis assumed a 10 percent reduction in traffic volumes.
The TDM alternative was modified from a 2% reduction of vehicle to a proposed 5% reduction in 2020 and a 10% proposed reduction in 2040. The preliminary 2% reduction of vehicle matched the growth rate of 1.5%. Also noted was that the SR 3 SB and SR 304 WB may experience up to a 30 percent of vehicles carrying two or more people resulting in 51% of total person-trips during peak traffic periods. The main reason for this high figure may be the result of a combination of the rideshare programs being sponsored by Kitsap Transit and the restrictive parking at the region’s defense facilities (Puget Sound Naval Shipyard, Navy Supply Center, Naval Base Kitsap at Bangor and the Kitsap Keyport Naval Base. Note: TDM was dropped as a stand-alone alternative due to the difficulty and the prohibitive cost of implementing an additional 5-10% vehicle reduction. Instead, the preferred alternatives are assumed to include TDM strategies.
Policy Point #3 Operational and Collision Analysis
Analysis Years and Analysis Periods Analysis Period(s):
The operational analysis results will be reported for the average weekday PM peak hour condition. Traffic data collection was performed along SR 3 and SR 304 during the week of April 15-18, 2013. Traffic data was collected for 5.5 hours from 1:30 to 7:00 PM. Twenty roadway tube counters were placed measuring rolling slow-downs; license plate reader cameras were placed at 4 locations to measure travel time; and manual turning movement counts were recorded along SR 304 at Charleston and Farragut Avenue gates.
Current Year:
Existing year traffic volumes were developed for all roadways and intersections in the study area using information from turning movement counts and tube counts collected between February 2010 and May 2014. Collision data was collected for the period of January 1, 2008 through December 31, 2012. The existing year for this study was assumed to be 2013, and collected traffic volumes were factored to 2013 traffic volumes.
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Policy Point #3 Operational and Collision Analysis Analysis Years and Analysis Periods Current Year continued
Note: opening year (2020) and future year (2040) traffic volumes were developed by assuming a 1.5 percent annual growth rate in traffic volumes between 2013 and the respective analysis year. The annual growth rate was based on a review of the following:
• Kitsap County 2010 and 2025 Travel Demand Models. • Puget Sound Regional Council 2006 and 2040 Travel Demand Models. • Bremerton Economic Development Study. • City of Bremerton Comprehensive Plan. • WSDOT Highway Segment Analysis Program historical trend line growth rates.
The alternatives analyzed in this study were not assumed to significantly change existing traffic patterns on a regional scale or how people travel. One traffic volume forecast was developed for the opening year (2020) and another for the future year (2040) analysis. This allowed for a conservative comparison that described how well each of the alternatives performed with a given set of volumes.
Opening Year (2020) Traffic Operations
No Build Alternative
Vehicle congestion is anticipated where SR 3 SB merges from two lanes to one lane, and where SR 304 WB merges from two lanes to one lane. The increased traffic volume modeled for the opening year (2020) results in substantially more congestion compared to 2013 existing conditions in the PM peak.
On SR 3 SB the duration of congestion is anticipated to increase from 2 hours 45 minutes with existing conditions to 4 hours 15 minutes with the No Build Alternative. Congestion would also extend beyond the limits of the study area, leaving approximately 460 unserved vehicles. This PM queuing also results in the Loxie Eagans on-ramp to SR 3 SB being blocked. Queuing along the on-ramp would extend back onto Loxie Eagans Boulevard.
At the Loxie Eagans Boulevard and the SR 3 SB ramps intersection, the stop-controlled SB approach would be over capacity due to left turn delay, and the resulting queue is anticipated to extend back to the auxiliary lane on SR 3 SB.
The duration of congestion on SR 304 WB would increase from 1 hour 45 minutes with existing conditions to 2 hours 30 minutes with the No Build Alternative, and congestion would extend beyond the limits of the study area, leaving approximately 175 unserved vehicles. Congestion on SR 3 NB and SR 304 EB in the PM peak would not change with the No Build Alternative compared to existing conditions. SR 3 NB between SR 16 and SR 304 would change from LOS E to LOS F in the AM peak (6:15 to 7:15 AM).
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Policy Point #3 Operational and Collision Analysis Analysis Years and Analysis Periods Opening Year (2020) Traffic Operations
SR 3 Build Alternatives
Note: Since the roadway configuration for the build alternatives on SR 3 NB and SR 304 EB do not change compared to the No Build Alternative, the traffic operations focus on the PM peak alternatives that reduce the bottleneck along SR 3 SB where two lanes currently merge into one lane.
The following alternatives are anticipated to experience congestion similar to the No Build alternative (this is due to the alternatives maintaining the merge condition from two lanes to one lane that is the source of PM peak congestion on SR 3 SB).
• SR 3 SB: Hard Shoulder Running: The merge location would be moved south, reducing the number of unserved vehicles compared to the No Build Alternative.
• Transportation Demand Management (TDM): the number of unserved vehicles would be reduced, because the traffic volumes are 5% lower compared to the No Build Alternative.
Travel times on SR 3 SB with the Hard Shoulder Running and TDM alternatives are similar to the No Build alternative.
For the Construct or Restripe and the Add Third Lanes alternatives, the merge condition on SR 3 SB would be eliminated, and congestion on SR 3 SB would be reduced. The Construct or Restripe Two Lanes alternatives with no ramp meter is anticipated to result in some congestion at the SR 304 on-ramp merge area due to the high volume of vehicles on the ramp. Average travel times on SR 3 SB with the Construct or Restripe, and Add Third Lane alternatives are modeled at over two minutes, compared to almost 10 minutes with the No Build alternative.
With all build alternatives, the queue from the SB off-ramp to Loxie Eagans Boulevard is anticipated to extend into the auxiliary lane on the SR 3 SB mainline, similar to the No Build Alternative.
SR 304 Build Alternatives
On SR 304 WB, the Add Third Lane Alternative would maintain two travel lanes to an add lane connection with SR 3 SB. This would relocate the HOV merge location that is the main source of congestion in the No Build Alternative, and substantially reduce congestion compared to the No Build alternatives. The GP and HOV travel times would improve compared to the No Build alternative due to the reduced congestion levels and the relocated HOV merge occurring at the add lane merge.
The Hard Shoulder Running and Construct or Restripe alternatives (no meter) would have similar congestion levels, congestion duration and unserved vehicles similar to the No Build Alternative with the SR 304 WB HOV merge relocated to 100 ft. west of the bridge.
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Policy Point #3 Operational and Collision Analysis Analysis Years and Analysis Periods Opening Year (2020) Traffic Operations
SR 304 Build Alternatives continued
With the Construct or Restripe alternative (with ramp meter), the duration of congestion would increase to 5 hours, and the number of unserved vehicles would increase to over 1,300. This is because the ramp meter restricts the number of vehicles able to pass through the ramp meter to well below the vehicle demand. The on-ramp meter was modeled to be activated for 5.5 hours for a worst case scenario.
Vehicle Hours of Delay and Throughput
Vehicle Hours of Delay provides a simple comparison across alternatives by summing the delay experienced by each driver in the network. In the opening year (2020), the Construct, or Restripe without a ramp meter and the Add Third Lane alternatives perform the best. The remaining alternatives perform similar to the No Build alternative. Vehicle throughput just south of the SR 3/SR 304 interchange is over 90 percent for all alternatives.
Intersection Operations
Opening year (2020), intersection LOS is anticipated to be better than a LOS D Urban threshold with the exceptions of the Loxie Eagans Boulevard and the SR 3 SB off-ramp intersection. The stop-controlled SR 3 SB off-ramp worsens from LOS E to F, and is over capacity during the peak hour. The resulting queue is anticipated to extend to the SR 3 mainline auxiliary lane. The Sam Christopherson intersection located at the end of the study area in Gorst is LOS E in 2020.
Design Year (2040) Traffic Operations Corridor Operations
No Build Alternative
The No Build Alternative is anticipated to experience congestion and queuing beyond the study limits where SR 3 SB merges from two lanes to one, and where SR 304 WB merges from two lanes to one. The assumed increase in traffic volumes for the future year (2040) would result in increased congestion compared to existing conditions and the opening year (2020).
On SR 3 SB, the duration of congestion is anticipated to increase to 5 hours with the No Build alternative. Congestion would also extend beyond the study area, leaving over 4,500 unserved vehicles. It is likely that congestion would not reach such severe conditions, as people would divert or eliminate trips to avoid congestion. Note: This study assumed traffic volumes and traffic patterns to be the same across all alternatives. This allows for a conservative comparison that describes how well each of the alternatives performs with a given set of volumes.
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Policy Point #3 Operational and Collision Analysis Analysis Years and Analysis Periods Design Year (2040) Traffic Operations Corridor Operations
No Build Alternative continued
At the Loxie Eagans Boulevard and SR 3 SB ramps intersection, the stop-controlled SB left turn approach would be over capacity, and the resulting queue would extend back to the auxiliary lane on SR 3 SB, and impact the two travel lanes as drivers slow to enter the queue in the auxiliary lane.
The duration of congestion on SR 304 WB would also increase to 4 hours 45 minutes with the No Build alternative, and congestion would extend beyond the limits of the study area, leaving approximately 1,900 unserved vehicles. Congestion in the non-peak direction, on SR 3 NB and on SR 304 EB, is not anticipated to change with the No Build Alternative compared to existing PM peak conditions.
SR 3 Build Alternatives
With all build alternatives, the roadway configuration on SR 3 NB and SR 304 EB would not be modified compared to the No Build Alternative, and traffic operations in the PM peak would not change.
The following two alternatives are anticipated to experience congestion similar to the No Build Alternative since each alternative maintains the source of congestion which is the merge condition from two lanes to one lane along SR 3 SB.
• SR 3 SB Hard Shoulder Running moves the merge location south, reducing the number of unserved vehicles compared to the No Build alternative.
• TDM alternative reduces the number of unserved vehicles because traffic volumes are 10% lower.
The Construct or Restripe (with and without a ramp meter), and the Add Third Lane alternatives would eliminate the merge condition on SR 3 SB, and reduce congestion on SR 3 SB compared to the No Build Alternative. The Construct or Restripe Two Lanes (both with and without a ramp meter) would result in congestion and queuing at the SR 304 on-ramp merge area due to the high expected vehicle volume on the ramp. The average travel times on SR 3 SB with the Construct or Restripe, and Add Third Lane alternatives are anticipated to range from approximately 3 to 7 minutes, compared to over 14 minutes with the No Build alternative.
With all build alternatives, the queue from the SB off-ramp to Loxie Eagans Boulevard is anticipated to extended into the auxiliary lane on the SR 3 SB mainline similar to the No Build alternative.
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Policy Point #3 Operational and Collision Analysis Analysis Years and Analysis Periods Design Year (2040) Traffic Operations Corridor Operations
SR 304 Build Alternatives
On SR 304, the Add Third Lane alternative would maintain two travel lanes to the connection with SR 3 SB. This would relocate the HOV merge which is the main source of congestion in the No Build alternative.
The Hard Shoulder Running and Construct or Restripe without a ramp meter have similar congestion levels, congestion duration, and unserved vehicles similar to the No Build alternative since the HOV merge location is extended to the beginning of the bridge. Since the ramp meter restricts throughput of GP lanes below the vehicle demand, the duration of congestion increases to 5 hours and the number of unserved vehicles increases to approximately 4,400.
Intersection LOS is anticipated to worsen compared to existing and opening year conditions at all study intersections. Vehicle hours of delay increases substantially compared to the opening year (2020) for all alternatives except for the Add Third Lane. Vehicle throughput just south of the SR 3/SR 304 interchange drops below 90 percent with all alternatives except the Add Third Lane alternative.
Study Area and Project Limits The study area includes; SR 3 in Kitsap County and SR 304 in Bremerton. SR 3 between Werner Road/Loxie Eagans interchange to the north, and the Sam Christopherson Avenue intersection to the south; the SR 3/SR 16 interchange; and SR 304 between Farragut Avenue and SR 3. Numbered Locations
1. Werner Road/Loxie Eagans Blvd & Auto Center Way/Oyster Bay Ave.
2. Loxie Eagans Blvd & SR 3 SB Ramps
3. Loxie Eagans Blvd & SR 3 NB Ramps
4. Farragut Ave/Cambrian Ave & SR 304
5. Charleston Beach Road & SR 304
6. Sam Christopherson Ave & SR 3
SR 3/SR 304 Bremerton Interchange Improvements Study Area
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Policy Point #3 Operational and Collision Analysis continued
Traffic Operations Analysis Methodology:
The traffic analysis focused on three periods with a straight line growth rate of 1.5% in the PM peak period.
• Existing Year 2013 • Opening Year 2020 • Forecast Year 2040
Software:
The following traffic models were used to analyze traffic operations:
1. Synchro (version 8.0) is a deterministic model used to calculate peak hour vehicle delay and LOS at intersections, similar to the methodologies outlined in the HCM. The model included all mainline sections, ramps, and intersections in the study area. Vehicle throughput, travel times, speeds and queues in the AM and PM peak.
2. VISSIM (version 5.4-9 and/or 5.4-10) is a stochastic model (microsimulation) that accounts for variability in driver behavior and is used to calculate travel times, speeds, and congestion levels for multiple modes of travel over long periods of time. VISSIM was used for the PM peak period.
3. Highway Capacity Manual Software (HCM 2010) was used for the AM peak on SR 3 mainline and SR 304 mainline.
Results to be reported:
A VISSIM model was used to analyze the mainline sections of SR 3 from just north of Werner Road/Loxie Eagans Blvd. interchange to the SR 16 ramp in Gorst to account for mainline queuing and SR 304 from the interchange with SR 3 to Farragut Avenue. A Synchro model was used to evaluate intersection operations at 1) Charleston Blvd/SR 304, Farragut Avenue/SR 304, Loxie Eagans/Auto Center, Loxie Eagans/SR 3 SB ramp terminal, and Loxie Eagans/SR 3 NB ramp terminal. The following alternatives were analyzed:
Existing Year 2013
• No Build
Opening Year 2020
• No Build • Hard Shoulder • Restripe/Construct • Add 3rd Lane • TDM 2% & 5%
Design Year 2040
• No Build • Hard Shoulder • Restripe/Construct • Add 3rd Lane • TDM 2% & 10%
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Policy Point #3 Operational and Collision Analysis continued
Travel Forecast A 1.5% straight line growth rate for mainline volumes was used (closely matching Kitsap County’s land use model rates). This growth rate is approximately a 10% overall growth from 2013 to 2020. This rate was chosen after reviewing applicable historical trends and land use travel demand models.
The Kitsap County land use model forecasts a negative growth rate of the SR 304 WB on-ramp to SR 3 SB. The consultant used a positive annual growth rate rather than a negative for this specific ramp. The historical AADT from 2004 to 2013 for this ramp shows a positive growth. The prior City of Bremerton’s Comprehensive Plan growth rates were not considered as they appear high for existing count data.
Network Assumptions The local network was assumed to have no changes in 2013, 2020, and 2040.
For the preferred Stage 1 Restripe Alternative, Year 2020 would include SR 3 SB mainline being 2 lanes and the SR 304 WB HOV merge being relocated to 100 ft. west of the bridge.
For the preferred Stage 2 Add Lane Alternative, Year 2020 and 2040 would include SR 3 WB mainline being 3 lanes between Gorst and Bremerton and SR 304 WB HOV merge being relocated to the beginning of the SB add lane merge.
Traffic Volume Development Tube counts were used for current year analysis and were performed in April of 2013 during the weekday (Wednesday, April 17). Turning movement counts were also done in 2013. The Loxie Eagans Boulevard turning movements and tube counts were conducted in 2014. Other available counts would have been used and factored to Year 2013 volumes (within 3 years of 2013). Forecast years assumed a 1.5 % growth rate.
Selection of Measures of Effectiveness The following matrices were used to demonstrate how each alternative will accomplish its stated objectives.
• Vehicle Throughput • Travel Time • Vehicle Hours of Delay • Duration of Congestion • Unserved Vehicles
SR3/SR 304 Bremerton Interchange Improvements Project May 19, 2015 Methods & Assumptions Document
Appendix A Revised October 21, 2015 SR 3/SR 304 Interchange Project Page A26 of 30
Policy Point #3 Operational and Collision Analysis continued
Collision Analysis SR 3: Summary and Assumptions
The alternatives likely to impact the safety performance of SR 3 from SR 16 to SR 310 are:
• Transportation Demand Management (TDM) • All Day Hard Shoulder Running (Restripe early merge into late merge on SR 3 SB and
SR 304 WB lane reductions) • Restripe or Widen to create SR 304 WB parallel on ramp merge and 2 lanes SB under
the SR 304 WB bridge • Add lane on SR 3 SB between SR 16 and SR 304
SR 3 was analyzed using the Highway Safety Manual freeway model Interchange Safety Analysis Tool enhanced (ISATe) software. It was divided into the following eight segments that totaled 3.46 miles (see attachments):
• Segment 1: SR 3/SR 16 Interchange to Sherman Heights Road/Railroad Bridge Vicinity (0.30 mile)
• Segment 2: Sherman Heights Road/Railroad Bridge to Sinclair Inlet Vicinity (0.65 mile)
• Segment 3: Sinclair Inlet Vicinity to Wright Creek Vicinity/SR 304 WB merge (0.64 mile) • Segment 4: SR 304 WB Merge Vicinity (0.34 mile)
• Segment 5: SR 3/SR 304 Interchange Vicinity (0.29 mile)
• Segment 6: SR 3/SR 304 Interchange to Werner/Loxie Eagans Interchange (0.30 mile)
• Segment 7: Werner/Loxie Eagans Interchange Vicinity (0.58 mile)
• Segment 8: Werner/Loxie Eagans Interchange to SR 310 Interchange (0.36 mile)
Assumptions:
Reducing existing 2013 volumes by 10% and 5% and assuming traffic volume will not change over a 5 year analysis period, will simulate the effect of the TDM alternative(s).
To analyze short-term build and no build effects, the build analyses was performed with a 10% and 5% reduction and no traffic growth over a 5-year period even though traffic may increase at a rate of 1.5% straight line.
The 5-year historical crash record (January 1, 2009 to December 31, 2013) had a total of 273 crashes which would average out to 54.6 crashes per year. There was a total of 119 multiple rear-end and 70 sideswipe crashes on the 3.46 mile mainline.
The predicted crash results are summarized below in the table (more detailed report summaries are attached). The “Predicted Widen or Restripe Crashes” would be most similar to a “Predicted No Build” Scenario (4-lane verses existing 3-lane in Segment 5).
SR3/SR 304 Bremerton Interchange Improvements Project May 19, 2015 Methods & Assumptions Document
Appendix A Revised October 21, 2015 SR 3/SR 304 Interchange Project Page A27 of 30
Policy Point #3 Operational and Collision Analysis Collision Analysis continued
SR 3 Summary and Assumptions continued
The build alternatives ranked in relative order by total predicted crashes are:
1. 10% TDM Alternative 2. Add Lane Alternative(s) 3. 5% TDM Alternative 4. Widen or Restripe Alternative (and Hard Shoulder Alternative)
SR 304: Summary and Assumptions
The build alternative likely to impact the safety performance of the SR 304 Urban Arterial from SR 3 to Farragut intersection is the Transportation Demand Management (TDM) alternative.
SR 304 was analyzed as a 4-lane divided urban arterial with no commercial access breaks using Highway Safety Manual (HSM) Urban and Suburban arterial software. In addition to 4 lanes for GP, SR 304 has two inside High Occupancy Vehicle (HOV) lanes.
SR 304 was segmented into two parts with each having one signalized intersection. The first segment is from SR 3 to Charleston intersection with 45 mph posted speed (Milepost 0.00 to Milepost 0.75). The second segment is from Charleston to Farragut intersection with 30 mph posted speed (Milepost 0.75 to Milepost 1.25).
Predicted and Observed Crashes for the TDM and Add Lane Alternatives
Predicted 10% TDM Crashes
Predicted 5% TDM
Crashes
Predicted Widen or Restripe Crashes
(Close to No Build)
Predicted Add Lane Crashes
5-Year Total Estimated Crashes 420.6 449.5 478.7 436.3
Estimated Average Crashes/Year 70.1 74.9 79.8 72.7
Estimated Multiple rear-ends 147.3 164.0 181.0 157.5
Estimated Multiple sideswipes 49.8 55.5 61.3 53.2
SR3/SR 304 Bremerton Interchange Improvements Project May 19, 2015 Methods & Assumptions Document
Appendix A Revised October 21, 2015 SR 3/SR 304 Interchange Project Page A28 of 30
Policy Point #3 Operational and Collision Analysis Collision Analysis continued
SR 304 Summary and Assumptions continued
Assumptions:
To analyze short-term and no build effects, the build analysis was performed with a 10% and 5% reduction and assumed no traffic growth over a 5-year period even though traffic may increase at a rate of 1.5% straight line. The 5-year historical crash record (January 1, 2009 to December 31, 2013) averaged 25 crashes per year. The total average crashes per year results are summarized below in the table (more detailed report summaries are attached).
Summary of total anticipated safety performance (average crashes per year)
Predicted 10% TDM
Crashes per Year
Predicted 5% TDM Crashes per Year
Predicted No Build Crashes
per Year
Expected No Build Crashes
per Year
Potential for No Build Safety
Improvement
Actual 5-Yr Averaged
Crashes per Year History
12.5 13.4 14.3 22.1 7.8 25.0
The TDM Alternative(s) would reduce crashes, but since SR 304 is already experiencing more crashes than predicted for similar type facilities the crash reduction would be low.
Because the prior 5-year crash history and expected crashes over the next 5 years with zero traffic growth are greater than the predicted crashes (other similar facilities), the TDM alternatives will likely experience more crashes than predicted.
Policy Point #4 Access Connections and Design
When WSDOT performed the traffic data collection in April 2013, no aircraft carriers were in port at the Bremerton Shipyard. WSDOT in consultation with the consultant and stakeholders decided that no adjustments to the traffic count data were needed to capture the additional traffic demand out of the Bremerton Shipyard when one or two aircraft carriers are in port.
Excerpts from the Navy’s 2012 Vehicle and Pedestrian Safety Study indicates that one aircraft carrier in port may produce between 173-221 additional vehicles leaving the Charleston Boulevard gate turning onto SR 304 WB.
Because the existing year (2013) PM peak volumes on SR 304 WB toward SR 3 SB is already approaching or at capacity for the SR 3/SR 304 interchange, the additional traffic from one or more aircraft carriers will not significantly change no build throughput results.
SR3/SR 304 Bremerton Interchange Improvements Project May 19, 2015 Methods & Assumptions Document
Appendix A Revised October 21, 2015 SR 3/SR 304 Interchange Project Page A29 of 30
Policy Point #4 Access Connections and Design continued
For example, the GP lane queuing on SR 304 WB blocks the signalized SR 304/Charleston intersection from about 4-4:14 PM in the 2013 simulation. When this signalized intersection is blocked by the SR 304 WB queue, no additional GP left turn traffic can proceed out of Charleston Gate intersection.
Even though the data indicates one additional carrier will generate about 200 additional left turn vehicles out of the Charleston Gate towards SR 304 WB, not much more GP traffic can “get through” in a one hour PM peak under the no build scenario(s).
However, an exception would be an extended SR 304 WB HOV lane on-ramp into an add lane build scenario. A SR 304 WB HOV lane may attract additional HOV traffic, but up to 30 % measured HOV volumes on SR 304 WB already appears to be a high percentage.
Policy Point #5 Land Use and Transportation Plans
The following comprehensive plans, studies or documents will be discussed and summarized:
• WSDOT’s 2007-2026 Highway System Plan (HSP
• 1996 SR 3/SR 304 Bremerton Ferry Terminal to Vicinity Gorst FEIS.
• 1999 VE study SR 3 Gorst Railroad Bridge to SR 3/SR 304 interchange
• 2004 Bremerton Comprehensive Plan
• 2006 Kitsap County Comprehensive Plan
• 2010 Bremerton Economic Development Study (BEDS)
• 2011 Scoping SR 3/SR 304 Interchange SB Improvements
• 2012 Naval Base Kitsap’s vehicle and Pedestrian Safety study
• 2013-2019 Kitsap Transit Development Plan
• SR 3/SR 16 Gorst Feasibility Study
Policy Point #6 Future Interchanges
This policy point is not applicable since the proposal is not expected to create new access points.
SR3/SR 304 Bremerton Interchange Improvements Project May 19, 2015 Methods & Assumptions Document
Appendix A Revised October 21, 2015 SR 3/SR 304 Interchange Project Page A30 of 30
Policy Point #7 Coordination
Initially no assumptions regarding coordination were considered beyond the funds appropriated by the legislature for initial development of the project, however, current transportation revenue legislation that is currently in front of the legislature proposes further funds for the SR 3/SR 304 project.
Policy Point #8 Environmental Processes
Based on the degree of impacts associated with the planned improvement, it is envisioned that the assumed environmental document type for the proposed improvement would be a documented Categorical Exclusion (CE).
APPENDIX B_____________________________________
SR 3 and SR 304: Additional Traffic Information
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Appendix B SR 3 and SR 304: Additional Traffic Information
Below is a summary table for intersections located with the project limits (5 signalized intersections and 1 unsignalized intersection). SR 3 and SR 304 Bremerton Interchange Improvement Project Synchro LOS and Delay (seconds/vehicle)
Intersection 2013 AM
2020 AM
2040 AM 2013
PM 2020 PM
2040 PM
SR 3 and Christopherson
LOS C C D E E F Delay 26.7 30.8 46.0 64.3 65.7 151.4
SR 304 and Charleston
LOS B B C C C E Delay 16.2 17.4 28.5 27.9 29.2 73.4
SR 304 and Farragut
LOS B B C C C F Delay 17.4 20.0 31.2 31.8 34.6 108.4
Auto Center and Loxie Eagans
LOS C B C C C D Delay 21.3 19.5 24.1 28.4 32.8 49.1
SR 3 and Loxie Eagans NB off and on
LOS A A B A B B
Delay 9.4 9.9 14.9 9.7 10.1 15.0
SR 3 and Loxie Eagans SB off and on (unsignalized)
LOS F F F F F F
Delay 222.6 3567.2 3562.5 43.8 (170.9) 2460.2 2459.1
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Appendix C Revised October 21, 2015 SR 3/SR 304 Interchange Project Page C1 of 26
APPENDIX C_____________________________________
Collision Data Analysis for SR 3 Freeway Alternatives Safety Analysis Documentation
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Collision Data Analysis for SR 3 Freeway Alternatives Safety Analysis Documentation
Prepared by: Forest Sutmiller
Washington State Department of Transportation WSDOT Olympic Region Planning
UNDER 23 U.S. CODE § 409, SAFETY DATA, REPORTS, SURVEYS, SCHEDULES, LISTS COMPILED OR COLLECTED FOR THE PURPOSE OF IDENTIFYING, EVALUATING, OR PLANNING THE SAFETY ENHANCEMENTS OF POTENTIAL CRASH SITES, HAZARDOUS ROADWAY CONDITIONS, OR RAILWAY-HIGHWAY CROSSINGS ARE NOT SUBJECT TO DISCOVERY OR ADMITTED INTO EVIDENCE IN A FEDERAL OR STATE COURT PROCEEDING OR CONSIDERED FOR OTHER PURPOSES IN ANY ACTION FOR DAMAGES ARISING FROM ANY OCCURRENCE AT A LOCATION MENTIONED OR ADDRESSED IN SUCH REPORTS, SURVEYS, SCHEDULES, LISTS, OR DATA. SR 3: Summary and Conclusions The alternatives likely to impact the safety performance of SR 3 from SR 16 to SR 310 are:
• Transportation Demand Management (TDM) • All Day Hard Shoulder Running (Restripe early merge into late merge on SR 3
SB and SR 304 WB lane reductions) • Restripe or Widen to create SR 304 WB parallel on ramp merge and 2 lanes SB
under the SR 304 WB bridge • Add lane on SR 3 Southbound between SR 16 and SR 304
SR 3 was analyzed using the Highway Safety Manual freeway model Interchange Safety Analysis Tool enhanced (ISATe) software. It was divided into the following eight segments that totaled 3.46 miles (see attachments):
• Segment 1: SR 3/SR 16 Interchange to Sherman Heights Road/Railroad Bridge Vicinity (0.30 mile)
• Segment 2: Sherman Heights Road/Railroad Bridge to Sinclair Inlet Vicinity (0.65 mile)
• Segment 3: Sinclair Inlet Vicinity to Wright Creek Vicinity/SR 304 Westbound merge (0.64 mile)
• Segment 4: SR 304 Westbound Merge Vicinity (0.34 mile) • Segment 5: SR 3/SR 304 Interchange Vicinity (0.29 mile) • Segment 6: SR 3/SR 304 Interchange to Werner/Loxie Eagans Interchange (0.30
mile) • Segment 7: Werner/Loxie Eagans Interchange Vicinity (0.58 mile) • Segment 8: Werner/Loxie Eagans Interchange to SR 310 Interchange (0.36 mile)
Appendix C Revised October 21, 2015 SR 3/SR 304 Interchange Project Page C4 of 26
Assumptions: Reducing existing 2013 volumes by 10% and 5% and assuming traffic volume will not change over a 5 year analysis period, will simulate the effect of the TDM alternative(s). To analyze short-term build and no build effects, I performed the build analyses with a 10% and 5% reduction and no traffic growth over a 5-year period even though traffic may increase at a rate of 1.5% straight line (no growth in past 4-years and over capacity condition on SR 3 SB and SR 304 WB in PM peak may limit growth). The 5-year historical crash record (January 1, 2009 to December 31, 2013) had a total of 273 crashes which would average out to 54.6 crashes per year. There were a total of 119 rear-ends and 70 sideswipe crashes on the 3.46 mile mainline. The predicted crash results are summarized below in the table (more detailed report summaries are attached). The “Predicted Widen or Restripe Crashes” would be most similar to a “Predicted No Build” Scenario (4-lane verses existing 3-lane in Segment 5).
Predicted and Observed Crashes for the TDM and Add Lane Alternatives
Predicted 10% TDM Crashes
Predicted 5% TDM
Crashes
Predicted Widen or Restripe Crashes
(Close to No Build)
Predicted Add Lane Crashes
5-Year Total Estimated Crashes
420.6 449.5 478.7 436.3
Estimated Average Crashes/Year
70.1 74.9 79.8 72.7
Estimated Rear-ends 147.3 164.0 181.0 157.5
Estimated Sideswipes 49.8 55.5 61.3 53.2
Conclusions: The build alternatives ranked in relative order by total predicted crashes are:
1. 10% TDM Alternative. 2. Add Lane Alternative(s). 3. 5% TDM Alternative. 4. Widen or Restripe Alternative (and Hard Shoulder Alternative)
Appendix C Revised October 21, 2015 SR 3/SR 304 Interchange Project Page C5 of 26
SR 3 and SR 304 Alternatives Safety Information (by analysis segment)
UNDER 23 U.S. CODE § 409, SAFETY DATA, REPORTS, SURVEYS, SCHEDULES, LISTS COMPILED OR COLLECTED FOR THE PURPOSE OF IDENTIFYING, EVALUATING, OR PLANNING THE SAFETY ENHANCEMENTS OF POTENTIAL CRASH SITES, HAZARDOUS ROADWAY CONDITIONS, OR RAILWAY-HIGHWAY CROSSINGS ARE NOT SUBJECT TO DISCOVERY OR ADMITTED INTO EVIDENCE IN A FEDERAL OR STATE COURT PROCEEDING OR CONSIDERED FOR OTHER PURPOSES IN ANY ACTION FOR DAMAGES ARISING FROM ANY OCCURRENCE AT A LOCATION MENTIONED OR ADDRESSED IN SUCH REPORTS, SURVEYS, SCHEDULES, LISTS, OR DATA. SR 3 Mainline is broken down into eight segments for analysis. The segments are:
• Segment 1, Milepost 34.51 to Milepost 34.81, 5-lane segment between SR 3/SR 16 Interchange to Sherman Heights Road/Railroad Bridge Vicinity.
• Segment 2, Milepost 34.81 to Milepost 35.46, 4-lane segment with 3 horizontal
curves in Sinclair Inlet Vicinity.
• Segment 3, Milepost 35.46 to Milepost 36.10, 4-lane segment in Sinclair Inlet Vicinity ending at the SR 304 Westbound merge.
• Segment 4, Milepost 36.10 to Milepost 36.44, 4-lane segment at SR 304 Westbound Merge.
• Segment 5, Milepost 36.44 to Milepost 36.73, 3-lane segment in SR 3/SR 304 Interchange Vicinity.
• Segment 6, Milepost 36.73 to Milepost 37.03, 4-lane segment between SR 3/SR
304 Interchange and Werner/Loxie Eagans Interchange.
• Segment 7, Milepost 37.03 to Milepost 37.61, 4-lane segment in Werner/Loxie Eagans Interchange Vicinity.
• Segment 8, Milepost 37.61 to Milepost 37.97, 4-lane segment between Werner/Loxie Eagans Interchange and SR 310 Interchange.
Appendix C Revised October 21, 2015 SR 3/SR 304 Interchange Project Page C6 of 26
Segment 1, SR 3 SB: Milepost 34.51 to Milepost 34.81 (& SR16 NB: MP 29.06 to MP 29.19) There were a total of 50 collisions between January 1, 2009 and December 31, 2013. There were 18 rear-ends, 16 sideswipes, 11 guardrail/jersey face/attenuator, 2 enter at angles, and 3 other. Rear-ends and sideswipes account for 68% of crashes over a 5-year period in this segment. Segment 1 Property
Damage Only
Possible Injury
Evident Injury
Serious Injury
Fatality
Year 2009 11 Year 2010 9 3 1 Year 2011 6 1 1 Year 2012 4 1 1 Year 2013 8 3 1
Segment 1, SR 3 SB: Milepost 34.51 to Milepost 34.81 (& SR16 NB: MP 29.06 to MP 29.19) Segment 1
Multiple-vehicle injury (not
ramp)
Single-
vehicle
injury (not
ramp)
Multiple- vehicle PDO (not
ramp)
Single-vehicle PDO (not
ramp)
2009 8 3 2010 4 7 2 2011 1 1 4 2 2012 1 1 3 1 2013 3 1 7 1
Appendix C Revised October 21, 2015 SR 3/SR 304 Interchange Project Page C7 of 26
Segment 2, SR 3 Milepost 34.81 to Milepost 35.46 There were a total of 54 collisions between January 1, 2009 and December 31, 2013. There were 19 rear-ends, 13 sideswipes, 7 guardrail/jersey face/attenuator, 5 underside of bridge, and 10 other. Rear-ends and sideswipes account for 59% of crashes over a 5-year period in this segment. Segment 2 Property
Damage Only
Possible Injury
Evident Injury
Serious Injury
Fatality
Year 2009 7 4 Year 2010 9 2 2 Year 2011 8 1 Year 2012 5 1 1 1 Year 2013 13
Segment 2
Multiple-vehicle injury (not
ramp)
Single-
vehicle
injury (not
ramp)
Multiple- vehicle PDO (not
ramp)
Single-vehicle PDO (not
ramp)
2009 3 3 5 2010 2 2 5 4 2011 1 6 2 2012 1 2 4 1 2013 12 1
Appendix C Revised October 21, 2015 SR 3/SR 304 Interchange Project Page C8 of 26
Segment 3, SR 3 Milepost 35.46 to Milepost 36.10 There were a total of 50 collisions between January 1, 2009 and December 31, 2013. There were 15 rear-ends, 15 sideswipes, 8 guardrail/jersey face/attenuator, and 12 other. Rear-ends and sideswipes account for 60% of crashes over a 5-year period in this segment. Segment 3 Property
Damage Only
Possible Injury
Evident Injury
Serious Injury
Fatality
Year 2009 6 1 1 Year 2010 9 Year 2011 6 2 Year 2012 11 1 Year 2013 10 2 1
Segment 3
Multiple-vehicle injury (not
ramp)
Single-
vehicle
injury (not
ramp)
Multiple- vehicle PDO (not
ramp)
Single-vehicle PDO (not
ramp)
2009 2 4 2 2010 7 2 2011 2 6 2012 1 6 5 2013 1 6 6
Appendix C Revised October 21, 2015 SR 3/SR 304 Interchange Project Page C9 of 26
Segment 4, SR 3 Milepost 36.10 to Milepost 36.44 There were a total of 13 collisions between January 1, 2009 and December 31, 2013. There were 6 rear-ends, 4 sideswipes, 1 jersey face, and 2 other. Rear-ends and sideswipes account for 77% of crashes over a 5-year period in this segment. Segment 4 Property
Damage Only
Possible Injury
Evident Injury
Serious Injury
Fatality
Year 2009 1 2 Year 2010 2 Year 2011 1 Year 2012 3 Year 2013 3 1
Segment 4, SR 3 Milepost 36.10 to Milepost 36.44 continued Segment 4
Multiple-vehicle injury (not
ramp)
Single-
vehicle
injury (not
ramp)
Multiple- vehicle PDO (not
ramp)
Single-vehicle PDO (not
ramp)
2009 2 1 2010 2 2011 1 2012 3 2013 1 2 1
Appendix C Revised October 21, 2015 SR 3/SR 304 Interchange Project Page C10 of 26
Segment 5, SR 3 Milepost 36.44 to Milepost 36.73 There were a total of 30 collisions between January 1, 2009 and December 31, 2013. There were 11 rear-ends, 11 sideswipes, 3 jersey face, and 5 other. Rear-ends and sideswipes account for 73% of crashes over a 5-year period in this segment. Segment 5 Property
Damage Only
Possible Injury
Evident Injury
Serious Injury
Fatality
Year 2009 1 Year 2010 4 2 Year 2011 8 Year 2012 5 1 Year 2013 8 1
Segment 5
Multiple-vehicle injury (not
ramp)
Single-
vehicle
injury (not
ramp)
Multiple- vehicle PDO (not
ramp)
Single-vehicle PDO (not
ramp)
2009 1 2010 2 3 1 2011 5 3 2012 1 4 1 2013 1 6 2
Appendix C Revised October 21, 2015 SR 3/SR 304 Interchange Project Page C11 of 26
Segment 6, SR 3 Milepost 36.73 to Milepost 37.03 There were a total of 23 collisions between January 1, 2009 and December 31, 2013. There were 13 rear-ends, 5 sideswipes, 2 jersey face, and 3 other. Rear-ends and sideswipes account for 78% of crashes over a 5-year period in this segment. Segment 6 Property
Damage Only
Possible Injury
Evident Injury
Serious Injury
Fatality
Year 2009 4 1 Year 2010 1 Year 2011 5 2 1 1 Year 2012 3 1 Year 2013 4
Segment 6
Multiple-vehicle injury (not
ramp)
Single-
vehicle
injury (not
ramp)
Multiple- vehicle PDO (not
ramp)
Single-vehicle PDO (not
ramp)
2009 3 2 2010 1 2011 3 6 2012 1 3 2013 3 1
Appendix C Revised October 21, 2015 SR 3/SR 304 Interchange Project Page C12 of 26
Segment 7, SR 3 Milepost 37.03 to Milepost 37.61 There were a total of 36 collisions between January 1, 2009 and December 31, 2013. There were 28 rear-ends, 2 sideswipes, 1 jersey face, and 5 other. Rear-ends and sideswipes account for 83% of crashes over a 5-year period in this segment. Segment 7 Property
Damage Only
Possible Injury
Evident Injury
Serious Injury
Fatality
Year 2009 1 2 1 Year 2010 9 2 1 Year 2011 4 Year 2012 7 2 Year 2013 3 1 2 1
Segment 7, SR 3 Milepost 37.03 to Milepost 37.61 Segment 7
Multiple-vehicle injury (not
ramp)
Single-
vehicle
injury (not
ramp)
Multiple- vehicle PDO (not
ramp)
Single-vehicle PDO (not
ramp)
2009 3 1 2010 3 6 3 2011 4 2012 2 7 2013 4 3
Appendix C Revised October 21, 2015 SR 3/SR 304 Interchange Project Page C13 of 26
Segment 8, SR 3 Milepost 37.61 to Milepost 37.97 There were a total of 17 collisions between January 1, 2009 and December 31, 2013. There were 9 rear-ends, 4 sideswipes, and 4 other. Rear-ends and sideswipes account for 76% of crashes over a 5-year period in this segment. Segment 8 Property
Damage Only
Possible Injury
Evident Injury
Serious Injury
Fatality
Year 2009 2 1 Year 2010 3 2 Year 2011 2 Year 2012 3 Year 2013 4
Segment 8
Multiple-vehicle injury (not
ramp)
Single-
vehicle
injury (not
ramp)
Multiple- vehicle PDO (not
ramp)
Single-vehicle PDO (not
ramp)
2009 1 1 1 2010 2 3 2011 1 1 2012 3 2013 4
Appendix C Revised October 21, 2015 SR 3/SR 304 Interchange Project Page C14 of 26
The chart below depicts severity type of collisions for SR 3 over a 5-year period from 2009 – 2013. Out of a total of 273 collisions recorded over the 5-year period; 4 resulted in a fatality; 212 were property damage only; 37 collisions resulted in a possible injury; 17 collisions recorded an evident injury; and 3 collisions recorded a serious injury.
5-Year Collision History for SR 3
212
37
17 3 4
Property Damage Only
Possible Injury
Evident Injury
Serious Injury
Fatality
Appendix C Revised October 21, 2015 SR 3/SR 304 Interchange Project Page C15 of 26
Collision Data Analysis for SR 304 Urban Arterial Alternatives Safety Analysis Documentation
Prepared by: Forest Sutmiller Washington State Department of Transportation
WSDOT Olympic Region Planning UNDER 23 U.S. CODE § 409, SAFETY DATA, REPORTS, SURVEYS, SCHEDULES, LISTS COMPILED OR COLLECTED FOR THE PURPOSE OF IDENTIFYING, EVALUATING, OR PLANNING THE SAFETY ENHANCEMENTS OF POTENTIAL CRASH SITES, HAZARDOUS ROADWAY CONDITIONS, OR RAILWAY-HIGHWAY CROSSINGS ARE NOT SUBJECT TO DISCOVERY OR ADMITTED INTO EVIDENCE IN A FEDERAL OR STATE COURT PROCEEDING OR CONSIDERED FOR OTHER PURPOSES IN ANY ACTION FOR DAMAGES ARISING FROM ANY OCCURRENCE AT A LOCATION MENTIONED OR ADDRESSED IN SUCH REPORTS, SURVEYS, SCHEDULES, LISTS, OR DATA. SR 304: Summary and Conclusions The build alternative likely to impact the safety performance of the SR 304 Urban Arterial from SR 3 to Farragut intersection is the Transportation Demand Management (TDM) alternative. SR 304 was analyzed as a 4-lane divided urban arterial with no commercial access breaks using Highway Safety Manual (HSM) Urban and Suburban arterial software. In addition to 4 lanes for general purpose, SR 304 has two inside High Occupancy Vehicle (HOV) lanes. I segmented SR 304 into two parts with each having one signalized intersection. The first segment is from SR 3 to Charleston intersection with 45 mph posted speed (Milepost 0.00 to Milepost 0.75). The second segment is from Charleston to Farragut intersection with 30 mph posted speed (Milepost 0.75 to Milepost 1.25). Assumptions: To analyze short-term and no build effects, I performed the build analysis with a 10% and 5% reduction and assumed no traffic growth over a 5-year period even though traffic may increase at a rate of 1.5% straight line. The 5-year historical crash record (January 1, 2009 to December 31, 2013) averaged 25 crashes per year. The total average crashes per year results are summarized below in the table (more detailed report summaries are attached).
Summary of total anticipated safety performance (average crashes per year) Predicted 10% TDM
Crashes per Year
Predicted 5% TDM Crashes per Year
Predicted No Build
Crashes per Year
Expected No Build
Crashes per Year
Potential for No Build Safety
Improvement
Actual 5-Yr Averaged
Crashes per Year History
12.5 13.4 14.3 22.1 7.8 25.0
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Conclusions: The TDM Alternative(s) would reduce crashes, but since SR 304 is already experiencing more crashes than predicted for similar type facilities the crash reduction would be low. Because the prior 5-year crash history and expected crashes over the next 5 years with zero traffic growth are greater than the predicted crashes (other similar facilities), the TDM alternatives will likely experience more crashes than predicted. There has been no traffic growth in the past 4 years and the over-capacity condition of SR 3 SB and SR 304 WB in the PM peak may limit growth.
SR 304 Alternatives Safety Information (by analysis segment and signal location)
UNDER 23 U.S. CODE § 409, SAFETY DATA, REPORTS, SURVEYS, SCHEDULES, LISTS COMPILED OR COLLECTED FOR THE PURPOSE OF IDENTIFYING, EVALUATING, OR PLANNING THE SAFETY ENHANCEMENTS OF POTENTIAL CRASH SITES, HAZARDOUS ROADWAY CONDITIONS, OR RAILWAY-HIGHWAY CROSSINGS ARE NOT SUBJECT TO DISCOVERY OR ADMITTED INTO EVIDENCE IN A FEDERAL OR STATE COURT PROCEEDING OR CONSIDERED FOR OTHER PURPOSES IN ANY ACTION FOR DAMAGES ARISING FROM ANY OCCURRENCE AT A LOCATION MENTIONED OR ADDRESSED IN SUCH REPORTS, SURVEYS, SCHEDULES, LISTS, OR DATA. SR 304 Mainline is broken down into two segments and two intersections for analysis. The segments and intersection locations are:
• Segment 1, Milepost 0.00 to Milepost 0.75, 4-lane segment (and HOV) from SR 3/SR 304 Interchange to City of Bremerton Incorporation limits where speed changes from 45 mph to 30 mph.
• Charleston Beach Road Intersection/Shipyard at Milepost 0.73 Vicinity.
• Segment 2, Milepost 0.75 to Milepost 1.25, 4-lane segment (and HOV) from City
of Bremerton Incorporation limits (Charleston Beach Road Intersection Vicinity) to Rodgers Street Vicinity (Farragut Street-Cambrian Avenue Vicinity).
• Farragut Street-Cambrian Avenue Intersection at Milepost 1.15.
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Segment 1, SR 304: Milepost 0.00 to Milepost 0.75 (Excluding intersection crashes) There were a total of 45 collisions between January 1, 2009 and December 31, 2013. There were 25 rear-ends, 15 sideswipes, and 5 other. Rear-ends and sideswipes account for 89% of crashes over a 5-year period in this segment. Segment 1 Property
Damage Only
Possible Injury
Evident Injury
Serious Injury
Fatality
Year 2009 14 Year 2010 8 2 Year 2011 8 2 Year 2012 5 1 Year 2013 5
Segment 1
Multiple-vehicle injury
Single-
vehicle
injury
Multiple- vehicle PDO
Single-vehicle PDO
2009 14 2010 1 1 8 2011 1 1 7 1 2012 1 5 2013 5
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Segment 1, SR 304: Milepost 0.00 to Milepost 0.75 (Excluding intersection crashes) Continued Charleston Beach Road Intersection, SR 304 Milepost 0.73 There were a total of 19 collisions between January 1, 2009 and December 31, 2013. There were 14 rear-ends, 2 sideswipes, and 3 other. Rear-ends and sideswipes account for 84% of crashes over a 5-year period in this segment. Charleston
Beach Road Property Damage
Only
Possible Injury
Evident Injury
Serious Injury
Fatality
Year 2009 1 Year 2010 2 1 1 Year 2011 1 Year 2012 4 3 1 Year 2013 3 2
Charleston Beach Road
Multiple-vehicle injury
Single-
vehicle
injury
Multiple- vehicle PDO (not
ramp)
Single-vehicle PDO
2009 1 2010 1 1 2 2011 1 2012 4 1 3 2013 2 2 1
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Segment 2, SR 304 Milepost 0.75 to Milepost 1.25 There were a total of 32 collisions between January 1, 2009 and December 31, 2013. There were 13 rear-ends, 13 sideswipes, and 6 other. Rear-ends and sideswipes account for 81% of crashes over a 5-year period in this segment. Segment 2 Property
Damage Only
Possible Injury
Evident Injury
Serious Injury
Fatality
Year 2009 4 2 Year 2010 4 1 Year 2011 4 2 Year 2012 2 2 1 Year 2013 8 1 1
Segment 2, SR 304 Milepost 0.75 to Milepost 1.25 continued
Segment 2
Multiple-vehicle injury
Single-
vehicle
injury
Multiple- vehicle PDO
Single-vehicle PDO
2009 1 1 4 2010 1 4 2011 1 1 3 1 2012 2 1 2 2013 2 8
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Farragut Street-Cambrian Avenue Intersection, SR 304 Milepost 1.15 There were a total of 29 collisions between January 1, 2009 and December 31, 2013. There were 16 rear-ends, 6 sideswipes, and 7 other. Rear-ends and sideswipes account for 76% of crashes over a 5-year period in this segment.
Farragut-Cambrian
Property Damage
Only
Possible Injury
Evident Injury
Serious Injury
Fatality
Year 2009 5 1 Year 2010 7 2 Year 2011 3 Year 2012 6 1 Year 2013 2 2
Farragut St. –Cambrian Ave.
Multiple-vehicle injury
Single-
vehicle
injury
Multiple- vehicle PDO
Single-vehicle PDO
2009 1 5 2010 2 7 2011 3 2012 1 6 2013 1 1 2
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APPENDIX D_________________________________________
SR 3 / SR 304 Bremerton Interchange Improvement Project Traffic Analysis Technical Memorandum
WSDOT
Parametrix
May 18, 2015
SR 3 / SR 304 Bremerton Interchange Improvement Project
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SR 3 / SR 304 Bremerton Interchange Improvement Project Traffic Analysis Technical Memorandum
WSDOT
Parametrix
May 18, 2015
SR 3 / SR 304 Bremerton Interchange Improvement Project
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SR 3 / SR 304 Bremerton Interchange Improvement Project
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Table of Contents Introduction .......................................................................................................................................................................................... 7
Methodology ........................................................................................................................................................................................ 7
Study Area ....................................................................................................................................................................................... 7
Traffic Volume Forecasts .................................................................................................................................................................. 8
Traffic Operations Models................................................................................................................................................................. 8
Existing Conditions .............................................................................................................................................................................. 8
Existing Roadway Configuration ....................................................................................................................................................... 8
Existing Traffic Operations ................................................................................................................................................................ 9
Corridor Operations ...................................................................................................................................................................... 9
Intersection Operations ................................................................................................................................................................. 9
Alternatives Evaluated ......................................................................................................................................................................... 9
Southbound SR 3: Hard Shoulder Running .................................................................................................................................... 10
Southbound SR 3: Construct or Restripe Two Lanes ...................................................................................................................... 10
Southbound SR 3: Add Third Lane from SR 304 to Gorst ............................................................................................................... 10
Transportation Demand Management ............................................................................................................................................ 10
SR 304: Convert HOV Lane to GP Lane ......................................................................................................................................... 10
Opening Year (2020) Traffic Operations............................................................................................................................................. 10
Corridor Operations ........................................................................................................................................................................ 10
No Build Alternative .................................................................................................................................................................... 10
Build Alternatives ........................................................................................................................................................................ 11
Intersection Operations .................................................................................................................................................................. 12
Future Year (2040) Traffic Operations ................................................................................................................................................ 12
Corridor Operations ........................................................................................................................................................................ 12
No Build Alternative .................................................................................................................................................................... 12
SR 3 / SR 304 Bremerton Interchange Improvement Project
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Build Alternatives ........................................................................................................................................................................ 13
Intersection Operations .................................................................................................................................................................. 14
Summary of Findings ......................................................................................................................................................................... 14
Appendix 1 Intersection Level of Service............................................................................................................................................ 18
Appendix 2: Congestion Diagrams ..................................................................................................................................................... 19
Appendix 3: Vehicle Throughput SR 3 Southbound, South of the SR 304 On-ramp ........................................................................... 27
Appendix 4: Travel Times .................................................................................................................................................................. 28
SR 3 Southbound ........................................................................................................................................................................... 28
SR 304 Westbound ........................................................................................................................................................................ 29
Appendix 5: Vehicle Hours of Delay ................................................................................................................................................... 31
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Introduction State Route (SR) 3 is a north-south highway in Kitsap County. The corridor provides a connection between Poulsbo to the north, and Shelton to the south and access to the Kitsap Naval Base, Silverdale, and Bremerton. SR 304 is an east-west arterial in Bremerton providing a connection between SR 3 to the west and the shipyard and ferry terminal to the east. These two state routes experience heavy weekday peak period congestion.
The purpose of this interchange improvement project is to evaluate modifications to the SR 3 / SR 304 interchange area to improve mobility and enhance safety. This study evaluates ways to reduce recurring congestion on SR 3 southbound and SR 304 westbound.
Methodology This section provides the methodology and assumptions used to evaluate the project’s effects on transportation operations. This section also includes the study area, existing year and future year transportation analysis, and evaluation criteria.
Study Area The study area includes; SR 3 between the Werner Road/Loxie Eagans interchange to the north, and the Sam Christopherson Avenue intersection to the south; the SR 3 / SR 16 interchange; and, SR 304 between Farragut Avenue and SR 3. Figure 1 illustrates the roadways and intersections analyzed in the study area, and Table 1 lists the study intersections.
Figure 1. Study Area
Table 1. Study Intersections
1 Werner Road/Loxie Eagans Boulevard and Auto Center Way/Oyster Bay Avenue
2 Loxie Eagans Boulevard and SR 3 Southbound Ramps 3 Loxie Eagans Boulevard and SR 3 Northbound Ramps 4 Farragut Avenue/Cambrian Avenue and SR 304 5 Charleston Beach Road and SR 304 6 Sam Christopherson Avenue and SR 3
SR 3 / SR 304 Bremerton Interchange Improvement Project
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Traffic Volume Forecasts Existing year traffic volumes for the 5-hour p.m. peak period (2:00 – 7:00 p.m.) were developed for all roadways and intersections in the study area using information from turn movement counts and tube counts collected between February 2010 and May 2014. Volumes were also developed for the 1:30 to 2:00 p.m. time period. This 30-minute period is included in the model to allow vehicles time to populate the network. The existing year for this study was assumed to be 2013, and collected traffic volumes were factored to match traffic volumes for 2013.
Opening year (2020), and future year (2040) traffic volumes were developed by assuming a 1.5 percent annual growth rate in traffic volumes between 2013 and the respective analysis year. The annual growth rate was based on a review of the following:
• Kitsap County 2010 and 2025 Travel Demand Models • Puget Sound Regional Council 2006 and 2040 Travel
Demand Models • Bremerton Economic Development Study (WSDOT,
2012) • City of Bremerton Comprehensive Plan
The alternatives analyzed in this study were not assumed to significantly change existing traffic patterns on a regional scale or how people travel. Some localized traffic pattern changes may occur as congestion increases, but were not analyzed to provide a conservative estimate. One traffic volume forecast was developed for the opening year (2020) and another for the future year (2040) analysis. This allows for a conservative comparison that describes how well each of the alternatives performs with a given set of volumes.
Traffic Operations Models Two traffic models were used to analyze traffic operations as follows:
• Synchro (version 8) is a deterministic model used to calculate peak hour vehicle delay and level of service (LOS) at intersections, similar to the methodologies outlined in the Highway Capacity Manual (HCM). LOS is expressed as a letter grade from A through F, and is used to measure how well, or how poorly an intersection operates. LOS A indicates the least amount of delay and best operations. LOS F indicates the highest amount of delay and worst operations.
• VISSIM (version 5.4) is a stochastic model (microsimulation) that accounts for variability in driver behavior and is used to calculate travel times, speeds, and congestion levels for multiple modes of travel over long periods of time.
Existing Conditions This section summarizes the existing transportation characteristics within the study area. This includes a description of the existing road network, traffic volumes, and existing roadway and intersection performance.
Existing Roadway Configuration SR 3 is a four-lane (two lanes each direction) separated highway in the vicinity of the Loxie Eagans Boulevard interchange. SR 3 southbound has an auxiliary lane between the Auto Center Way on ramp and the Loxie Eagans Boulevard off ramp, and SR 3 northbound has an auxiliary lane between the SR 304 westbound on ramp and the Loxie Eagans Boulevard off ramp.
SR 3 / SR 304 Bremerton Interchange Improvement Project
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At the SR 3 / SR 304 interchange, SR 3 southbound merges from two lanes to one lane. The SR 304 on ramp connects to SR 3 southbound as an add-lane, and SR 3 southbound maintains two lanes between SR 304 and SR 16. SR 3 northbound is also two lanes between SR 16 and SR 304.
North of Farragut Avenue, SR 304 is a four-lane arterial with a landscaped center median. South of Farragut Avenue, SR 304 is a six-lane arterial with a landscaped center median. In the westbound direction, the inside lane is a high occupancy vehicle (HOV) lane.
The HOV lane designation ends east of the SR 3 / SR 304 interchange, and the right lane drops at the off ramp to SR 3 northbound. The two remaining westbound lanes merge to one lane prior to the SR 304 westbound undercrossing.
Existing Traffic Operations Corridor Operations Findings from the analysis demonstrate that there are two locations in the study area where vehicle volumes exceed available roadway capacity during the p.m. commute period as follows:
• Where SR 3 southbound merges from two lanes to one lane south of the Loxie Eagans interchange: this location is congested for approximately 2 hours 45 minutes, and congestion extends back to the Loxie Eagans interchange.
• Where SR 304 westbound merges from two lanes to one lane east of the SR 3 / SR 304 interchange: This location is congested for approximately 1 hour 45 minutes. Congestion in the general purpose lane extends back to the Charleston Beach Road intersection. The HOV lane allows transit, vanpools
and carpools to bypass much of the congested general purpose (GP) lane, but HOV vehicles experience some congestion once the HOV lane terminates.
There is no substantial congestion on SR 3 northbound or SR 304 eastbound.
Congestion diagrams for SR 3 and SR 304 are shown in Appendix B. The congestion diagrams illustrate the lane configuration, travel speeds during the peak 15-minute period, and the duration of congestion.
In some cases, congestion extends to the limits of the model, and vehicles are effectively queuing outside of the model. When this occurs, the number of unserved vehicles is shown to the right of the congestion diagram
Intersection Operations Intersection LOS is summarized in Appendix A. All intersections operate at LOS D with two exceptions:
• Loxie Eagans Boulevard and SR 3 Southbound Ramps – the southbound approach to this stop-controlled intersection operates at LOS E during the p.m. peak hour.
• SR 3 and Sam Christopherson Boulevard – This signalized intersection operates at LOS E during the p.m. peak hour.
Alternatives Evaluated This section describes the roadway configuration for each of the five alternatives. One Alternative, the Construct or Restripe Two Lanes, was analyzed both with and without a ramp meter for the SR 304 GP lane, bringing the total number of alternatives to six.
SR 3 / SR 304 Bremerton Interchange Improvement Project
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Southbound SR 3: Hard Shoulder Running This alternative would provide hard shoulder running during peak travel times at the existing SR 3 merge from two lanes to one lane north of the SR 304 on-ramp. This alternative would still merge north of the SR 304 westbound add-lane, but the merge would take place south of the existing location.
Southbound SR 3: Construct or Restripe Two Lanes This alternative would modify the SR 3 / SR 304 interchange by maintaining two travel lanes on SR 3 southbound and changing the SR 304 on ramp from an add-lane to a merge lane. This modification could be accomplished through either a restripe, or constructing an additional lane—there is no difference between the traffic operations resulting from the two methods. This alternative was analyzed with and without a ramp meter for the SR 304 GP lane.
Southbound SR 3: Add Third Lane from SR 304 to Gorst This alternative would maintain two travel lanes on SR 3 southbound, and maintain the SR 304 ramp as an add-lane by adding a third southbound lane to SR 3 between the SR 304 interchange and Gorst, where it would tie into the existing three lane section leading to SR 16.
Transportation Demand Management This alternative provided a reduction in future traffic volumes through the implementation of transportation demand management (TDM) strategies. The focus of the traffic analysis was not on the specific strategies used, but on the effect of removing trips from the transportation network. The opening year (2020) analysis assumed a five percent reduction in traffic volumes, and the future year (2040) analysis assumed a 10 percent reduction in traffic volumes. Reference Figure 2 on Page 12.
SR 304: Convert HOV Lane to GP Lane This alternative would convert the SR 304 westbound HOV lane to a GP lane. No other changes were made to the merge location on SR 304 or SR 3.
Opening Year (2020) Traffic Operations Corridor Operations No Build Alternative Vehicle congestion is anticipated where SR 3 southbound merges from two lanes to one lane, and where SR 304 westbound merges from two lanes to one lane, as illustrated by the congestion diagrams in Appendix A. The increased traffic volume modeled for the opening year (2020) results in substantially more congestion compared to existing conditions.
On SR 3 southbound the duration of congestion is anticipated to increase from 2 hours 45 minutes with existing conditions to 4 hours 15 minutes with the No Build Alternative. Congestion would also extend to the start of the study area, leaving approximately 460 unserved vehicles.
At the Loxie Eagans Boulevard and SR 3 southbound ramps intersection, the stop-controlled southbound approach would be over capacity, and the resulting queue is anticipated to extend back to the auxiliary lane on SR 3 southbound.
The duration of congestion on SR 304 westbound would increase from 1 hour 45 minutes with existing conditions to 2 hours 30 minutes with the No Build Alternative, and congestion would extend to the start of the study area, leaving approximately 175 unserved vehicles.
SR 3 / SR 304 Bremerton Interchange Improvement Project
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Congestion on SR 3 northbound and SR 304 eastbound would not change with the No Build Alternative compared to existing conditions.
Build Alternatives SR 3 Because all the roadway configuration for all build alternatives on SR 3 northbound and SR 304 eastbound does not change compared to the No Build Alternative, the traffic operations are not anticipated to change and not included in this section.
As illustrated by the congestion diagrams in Appendix B, on SR 3 southbound, the following three alternatives are anticipated to experience congestion similar to the No Build Alternative (this is because the alternatives maintain the merge condition from two lanes to one lane that is the source of congestion on SR 3 southbound):
• SR 3 Southbound: Hard Shoulder Running: The merge location would be moved south, reducing the number of unserved vehicles compared to the No Build Alternative.
• Transportation Demand Management (TDM): the number of unserved vehicles would be reduced, because the traffic volumes are lower compared to the No Build Alternative.
• SR 304: Convert HOV Lane to GP Lane.
As summarized in Appendix 4, travel times on SR 3 southbound with the Hard Shoulder Running, TDM, and Convert HOV Lane Alternatives are similar to the No Build Alternative.
For the Construct or Restripe (with and without a ramp meter), and the Add Third Lane alternatives, the merge condition on SR 3 southbound would be eliminated, and congestion on SR
3 southbound would be reduced. The Construct or Restripe Two Lanes (no meter) is anticipated to result in some congestion at the SR 304 on-ramp merge area due to the high volume of vehicles on the ramp. Average travel times on SR 3 southbound with the Construct or Restripe, and Add Third Lane Alternatives are modeled at over two minutes, compared to almost ten minutes with the No Build Alternative.
With all build alternatives, the queue from the southbound off ramp to Loxie Eagans Boulevard is anticipated to extend into the auxiliary lane on the SR 3 southbound mainline, similar to the No Build Alternative.
SR 304 On SR 304 the Add Third Lane Alternative would maintain two travel lanes to the connection with SR 3 southbound. This would eliminate the merge location that is the main source of congestion in the No Build Alternative, and substantially reduce congestion compared to the No Build Alternative. GP and HOV travel times would improve compared to the No Build Alternative due to the reduced congestion levels.
The Hard Shoulder Running and Construct or Restripe (without a ramp meter) alternatives would have similar congestion levels, congestion duration, and unserved vehicles similar to the No Build Alternative.
With the Construct or Restripe (with a ramp meter) alternative, the duration of congestion would increase to 5 hours, and the number of unserved vehicles would increase to over 1,300. This is because the ramp meter restricts the number of vehicles able to pass through the ramp meter to well below the vehicle demand.
SR 3 / SR 304 Bremerton Interchange Improvement Project
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With the TDM Alternative, the number of unserved vehicles would be reduced because traffic volumes are lower compared to the No Build Alternative.
The Convert HOV Lane Alternative would reduce the number of unserved vehicles because GP vehicles would use the converted HOV lane, but the two GP lanes would still merge to one GP lane, resulting in congestion occurring on SR 304.
Vehicle Hours of Delay and Throughput Vehicle Hours of Delay provides a simple comparison across alternatives by summing the delay experienced by each driver in the network. As shown in Appendix 5, in the opening year (2020), the Construct, or Restripe without a ramp meter, and the Add Third Lane Alternatives perform the best. The remaining alternatives perform similar to the No Build Alternative.
As shown in Appendix 3, vehicle throughput just south of the SR 3 / SR 304 interchange is over 90 percent for all alternatives.
Intersection Operations As illustrated in Appendix A, opening year (2020), intersection LOS is anticipated to remain the same compared to existing conditions at all six study intersections with the exception of the Loxie Eagans Boulevard and SR 3 southbound ramps intersection. The stop-controlled SR 3 southbound off ramp worsens from LOS E to F, and is over capacity during the peak hour. The resulting queue is anticipated to extend to the SR 3 mainline auxiliary lane.
Future Year (2040) Traffic Operations Corridor Operations No Build Alternative As illustrated in Appendix 2, the No Build Alternative is anticipated to experience congestion where SR 3 southbound merges from two lanes to one, and where SR 304 westbound merges from two lanes to one. The assumed increase in traffic volumes for the future year (2040) would result in increased congestion compared to existing conditions and the opening year (2020).
On SR 3 southbound the duration of congestion is anticipated to increase to 5 hours with the No Build Alternative. Congestion would also extend to the start of the study area, leaving over 4,500 unserved vehicles. It is likely that congestion would not reach such severe conditions, as people would divert or eliminate trips to avoid the congestion. As described in the Methodology section above, this study assumed traffic volumes and travel patterns to be the same across all alternatives. This allows for a conservative comparison that describes how well each of the alternatives performs with a given set of volumes.
At the Loxie Eagans Boulevard and SR 3 southbound ramps intersection, the stop-controlled southbound approach would be over capacity, and the resulting queue would extend back to the auxiliary lane on SR 3 southbound, and impact the two travel lanes as drivers slow to enter the queue in the auxiliary lane.
The duration of congestion on SR 304 westbound would also increase to 4 hours 45 minutes with the No Build Alternative, and congestion would extend to the start of the study area, leaving approximately 1,900 unserved vehicles.
SR 3 / SR 304 Bremerton Interchange Improvement Project
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Congestion in the non-peak direction, on SR 3 northbound and SR 304 eastbound, is not anticipated to change with the No Build Alternative compared to existing conditions.
Build Alternatives SR 3 With all build alternatives, the roadway configuration on SR 3 northbound and SR 304 eastbound would not be modified compared to the No Build Alternative, and traffic operations would not change. This section summarizes the traffic operations for SR 3 southbound and SR 304 westbound in the vicinity of the SR 3 / SR 304 interchange area for the year 2040.
As illustrated by the congestion diagrams provided in Appendix B, on SR 3 southbound, the following three alternatives are anticipated to experience congestion similar to the No Build Alternative (this is because each alternative would maintain the merge condition from two lanes to one lane that is the source of congestion on SR 3 southbound):
• SR 3 Southbound Hard Shoulder Running: the merge location would be moved south, reducing the number of unserved vehicles compared to the No Build Alternative.
• TDM: the number of unserved vehicles would be reduced because the traffic volumes are lower; and,
• SR 304: Convert HOV Lane to GP Lane
As summarized in Appendix 4, travel times on SR 3 southbound with the Hard Shoulder Running, TDM, and Convert HOV Lane Alternatives are anticipated to be similar to the No Build Alternative.
The Construct or Restripe (with and without a ramp meter), and the Add Third Lane alternatives would eliminate the merge
condition on SR 3 southbound, and reduce congestion on SR 3 southbound compared to the No Build Alternative. The Construct or Restripe Two Lanes (both with and without a ramp meter) would result in some congestion at the SR 304 on-ramp merge area due to the high expected vehicle volume on the ramp. Average travel times on SR 3 southbound with the Construct or Restripe, and Add Third Lane Alternatives are anticipated to range from approximately 3 to 7 minutes, compared to over 14 minutes with the No Build Alternative.
With all build alternatives, the queue from the southbound off ramp to Loxie Eagans Boulevard is anticipated to extend into the auxiliary lane on the SR 3 southbound mainline, similar to the No Build Alternative.
SR 304 On SR 304 the Add Third Lane Alternative would maintain two travel lanes to the connection with SR 3 southbound. This would eliminate the merge location that is the main source of congestion in the No Build Alternative, and substantially reduce congestion compared to the No Build Alternative. GP and HOV travel times are expected to improve compared to the No Build Alternative.
The Hard Shoulder Running and Construct or Restripe without a ramp meter have similar congestion levels, congestion duration, and unserved vehicles similar to the No Build Alternative.
With the Construct or Restripe with a ramp meter the duration of congestion increases to 5 hours, and the number of unserved vehicles increases to approximately 4,400. This is because the ramp meter restricts throughput of GP well below the vehicle demand.
SR 3 / SR 304 Bremerton Interchange Improvement Project
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With the TDM Alternative, the number of unserved vehicles is reduced because traffic volumes are lower compared to the No Build Alternative.
The Convert HOV Lane Alternative reduces the number of unserved vehicles compared to the No Build Alternative because GP vehicles are able to utilize the converted HOV lane, but the two GP lanes still merge to one GP lane and congestion still occurs on SR 304.
Intersection Operations As illustrated in Appendix 1, in the future year (2040), intersection LOS is anticipated to worsen compared to existing conditions and opening year (2020) conditions at all study intersection, except for the Loxie Eagans Boulevard and SR 3 southbound ramps intersection, which is already operating at LOS F in the opening year (2020). The resulting queue spills back to the SR 3 mainline auxiliary lane.
Vehicle Hours of Delay and Throughput As shown in Appendix 5, vehicle hours of delay increases substantially compared to the opening year (2020) for all alternatives except for the Add Third Lane Alternative.
As shown in Appendix 3, vehicle throughput just south of the SR 3 / SR 304 interchange drops below 90 percent with all alternatives except the Add Third Lane Alternative.
Summary of Findings With the current corridor geometric configurations, the following locations cause congestion during the p.m. commute period:
• SR 3 southbound at the merge from two lanes to one lane
• SR 304 westbound at the merge from two lanes to one lane
With the anticipated growth in traffic volumes in the opening year (2020) and future year (2040), congestion levels are anticipated to increase, and travel times in the corridor would worsen.
The findings for the alternatives analysis are summarized in Figures 3 and 4, which provide a summary comparison ranking for the performance of each alternative based on throughput, travel time, vehicle hours of delay, duration of congestion, and unserved vehicles.
SR 3 / SR 304 Bremerton Interchange Improvement Project
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Figure 2. Transportation Demand Management Results
SR 3 / SR 304 Bremerton Interchange Improvement Project
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Figure 3. Summary of Findings: Opening Year (2020)
SR 3 / SR 304 Bremerton Interchange Improvement Project
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Summary of Findings: Future Year (2040) Figure 4
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Appendix 1: Intersection Level of Service
SR 3 / SR 304 Bremerton Interchange Improvement Project
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Appendix 2: Congestion Diagrams
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SR 3 / SR 304 Bremerton Interchange Improvement Project
Appendix D Revised October 21, 2015 SR 3/SR 304 Bremerton Interchange Improvements Project Page D21 of 31
SR 3 / SR 304 Bremerton Interchange Improvement Project
Appendix D Revised October 21, 2015 SR 3/SR 304 Bremerton Interchange Improvements Project Page D22 of 31
SR 3 / SR 304 Bremerton Interchange Improvement Project
Appendix D Revised October 21, 2015 SR 3/SR 304 Bremerton Interchange Improvements Project Page D23 of 31
SR 3 / SR 304 Bremerton Interchange Improvement Project
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SR 3 / SR 304 Bremerton Interchange Improvement Project
Appendix D Revised October 21, 2015 SR 3/SR 304 Bremerton Interchange Improvements Project Page D25 of 31
SR 3 / SR 304 Bremerton Interchange Improvement Project
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SR 3 / SR 304 Bremerton Interchange Improvement Project
Appendix D Revised October 21, 2015 SR 3/SR 304 Bremerton Interchange Improvements Project Page D27 of 31
Appendix 3: Vehicle Throughput SR 3 Southbound, South of the SR 304 On-ramp
0%
10%
20%
30%
40%
50%
60%
70%
80%
90%
100%
No Build Hard Shoulder Running Construct, or Restripe Add Lane from SR 304 toGorst
TDM
Percent of Demand Served (5-hr)
Year 2020 Year 2040
SR 3 / SR 304 Bremerton Interchange Improvement Project
Appendix D Revised October 21, 2015 SR 3/SR 304 Bremerton Interchange Improvements Project Page D28 of 31
Appendix 4: Travel Times SR 3 Southbound From north of Loxie Eagans to south of the SR 304 on-ramp
SR 3 / SR 304 Bremerton Interchange Improvement Project
Appendix D Revised October 21, 2015 SR 3/SR 304 Bremerton Interchange Improvements Project Page D29 of 31
SR 304 Westbound From north of Farragut to SR 3 south of the SR 304 on-ramp
0
5
10
15
20
25
30
35
40
No Build HardShoulderRunning
Construct, orRestripe
Add Lanefrom SR 304
to Gorst
TDM
2020 GP
Max.
Avg.
05
10152025303540
No Build HardShoulderRunning
Construct,or Restripe
Add Lanefrom SR304 toGorst
TDM
2020 HOV
Max.
Avg.
0
5
10
15
20
25
30
35
40
No Build HardShoulderRunning
Construct,or Restripe
Add Lanefrom SR 304
to Gorst
TDM
2040 GP
Max.
Avg.
05
10152025303540
No Build HardShoulderRunning
Construct,or Restripe
Add Lanefrom SR304 toGorst
TDM
2040 HOV
Max.
Avg.
SR 3 / SR 304 Bremerton Interchange Improvement Project
Appendix D Revised October 21, 2015 SR 3/SR 304 Bremerton Interchange Improvements Project Page D30 of 31
0
500
1000
1500
2000
2500
3000
No Build Hard Shoulder Running Construct, or Restripe Add Lane from SR 304 to Gorst TDM
Vehicle Hours of Delay
Year 2020 Year 2040
SR 3 / SR 304 Bremerton Interchange Improvement Project
Appendix D Revised October 21, 2015 SR 3/SR 304 Bremerton Interchange Improvements Project Page D31 of 31
Appendix 5: Vehicle Hours of Delay